6533b837fe1ef96bd12a3421
RESEARCH PRODUCT
Statistical Thermodynamics of Polymer Quantum Systems
Guillermo Chacón-acostaLeonardo DagdugElisa ManriqueHugo A. Morales-técotlsubject
Length scaleHigh Energy Physics - TheoryCanonical quantizationThermodynamicsFOS: Physical sciencesLoop quantum gravityGeneral Relativity and Quantum Cosmology (gr-qc)General Relativity and Quantum CosmologyQuantization (physics)canonical quantizationQuantum mechanicsstatistical thermodynamicsQuantumBlack hole thermodynamicsMathematical PhysicsCondensed Matter - Statistical MechanicsPhysicsQuantum geometryQuantitative Biology::BiomoleculesStatistical Mechanics (cond-mat.stat-mech)loop quantum gravitylcsh:Mathematics82B30 81S05 81Q65 82B20 83C45lcsh:QA1-939Ideal gasCondensed Matter::Soft Condensed MatterClassical mechanicsHigh Energy Physics - Theory (hep-th)Geometry and TopologyAnalysisdescription
Polymer quantum systems are mechanical models quantized similarly as loop quantum gravity. It is actually in quantizing gravity that the polymer term holds proper as the quantum geometry excitations yield a reminiscent of a polymer material. In such an approach both non-singular cosmological models and a microscopic basis for the entropy of some black holes have arisen. Also important physical questions for these systems involve thermodynamics. With this motivation, in this work, we study the statistical thermody- namics of two one dimensional polymer quantum systems: an ensemble of oscillators that describe a solid and a bunch of non-interacting particles in a box, which thus form an ideal gas. We first study the spectra of these polymer systems. It turns out useful for the analysis to consider the length scale required by the quantization and which we shall refer to as poly- mer length. The dynamics of the polymer oscillator can be given the form of that for the standard quantum pendulum. Depending on the dominance of the polymer length we can distinguish two regimes: vibrational and rotational. The first occur for small polymer length and here the standard oscillator in Schrodinger quantization is recovered at leading order. The second one, for large polymer length, features dominant polymer effects. In the case of the polymer particles in the box, a bounded and oscillating spectrum that presents a band structure and a Brillouin zone is found. The thermodynamical quantities calculated with these spectra have corrections with respect to standard ones and they depend on the poly- mer length. When the polymer length is small such corrections resemble those coming from the phenomenological generalized uncertainty relation approach based on the idea of the existence of a minimal length. For generic polymer length, thermodynamics of both systems present an anomalous peak in their heat capacity CV . In the case of the polymer oscillators this peak separates the vibrational and rotational regimes, while in the ideal polymer gas it reflects the band structure which allows the existence of negative temperatures.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2011-12-02 |